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I was reading this question because I'm trying to find the size of a function in a C++ program, It is hinted at that there may be a way that is platform specific. My targeted platform is windows

The method I currently have in my head is the following:
1. Obtain a pointer to the function
2. Increment the Pointer (& counter) until I reach the machine code value for ret
3. The counter will be the size of the function?

Edit1: To clarify what I mean by 'size' I mean the number of bytes (machine code) that make up the function.
Edit2: There have been a few comments asking why or what do I plan to do with this. The honest answer is I have no intention, and I can't really see the benefits of knowing a functions length pre-compile time. (although I'm sure there are some)

This seems like a valid method to me, will this work?

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And you want to do this because...? –  Etienne de Martel Apr 13 '11 at 21:08
Uncertain but if a function has multiple returns. Doesn't that mean you're getting flawed results ? –  Khez Apr 13 '11 at 21:08
What if there is more than one ret? What if the function is inlined? What if the function has sub-functions that have been inlined into it? –  Oliver Charlesworth Apr 13 '11 at 21:09
Did you read the comment at your linked question - "Why on Earth would anyone want to do that?". –  Bo Persson Apr 13 '11 at 21:11
It's sad to see so many negative responses to a question that could simply be in the pursuit of hard-to-obtain knowledge about computer architecture. We should give the OP the benefit of the doubt. –  Michael Chinen Apr 13 '11 at 21:25

12 Answers 12

up vote 8 down vote accepted

No, this will not work:

  1. There is no guarantee that your function only contains a single ret instruction.
  2. Even if it only does contain a single ret, you can't just look at the individual bytes - because the corresponding value could appear as simply a value, rather than an instruction.

The first problem can possibly be worked around if you restrict your coding style to, say, only have a single point of return in your function, but the other basically requires a disassembler so you can tell the individual instructions apart.

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The function will never be inlined if somewhere else in the program, he requests a function pointer to it. Agreed on the "This is generally not possible / difficult" notion though. –  Paul Betts Apr 13 '11 at 21:17
In addition, there's nothing that says that the compiled output for a function needs to be contiguous. Especially when optimizing, the compiler (and linker) will place blocks of code all over the place (before the function, maybe in the middle of another function), to try to avoid branches in code that it believes to be the 'hot' path, to place jump targets at particular alignments, or to coalesce identical instruction sequences (or whatever). The point being that there's yet one more thing that makes this a fools errand. –  Michael Burr Apr 13 '11 at 21:22
Following the sense of Michael's comment, it need not even contain a ret line at all. GCC sometimes does optimizations where it simply jumps into another function/block that contains the ret already. I suppose if it exits only with exceptions it might not have a return either. –  edA-qa mort-ora-y Apr 13 '11 at 21:26
Even if you modify your C/C++ coding style to have only one return per function, there's no guarantee that the compiler/optimizer emitted assembly code that does the same! –  Drew Hall Apr 13 '11 at 22:16
In addition to all the great arguments already raised, no one has mentioned that, in variable-width instruction sets (like x86), it is not even possible to reliably disassemble code without running it. For example, consider the assembly jmp Cont; db 01; Cont: ... That is, insert the byte 0x01 between the jmp statement and the next statement. When you are stepping through, there is no way for you to know that the 0x01 isn't the start of the next instruction, so everything disassembled after that point will be garbage. This is why it's so hard to write a disassembler for x86. –  BlueRaja - Danny Pflughoeft Apr 13 '11 at 22:54

It is possible to obtain all blocks of a function, but is an unnatural question to ask what is the 'size' of a function. Optimized code will rearrange code blocks in the order of execution and will move seldom used blocks (exception paths) into outer parts of the module. For more details, see Profile-Guided Optimizations for example how Visual C++ achieves this in link time code generation. So a function can start at address 0x00001000, branch at 0x00001100 into a jump at 0x20001000 and a ret, and have some exception handling code 0x20001000. At 0x00001110 another function starts. What is the 'size' of your function? It does span from 0x00001000 to +0x20001000, but it 'owns' only few blocks in that span. So your question should be unasked.

There are other valid questions in this context, like the total number of instructions a function has (can be determined from the program symbol database and from the image), and more importantly, what is the number of instructions in the frequent executed code path inside the function. All these are questions normally asked in the context of performance measurement and there are tools that instrument code and can give very detailed answers.

Chasing pointers in memory and searching for ret will get you nowhere I'm afraid. Modern code is way way way more complex than that.

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Btw, this is what I do to see the 'size' of a function: load the module in Windbg, then uf module!functioname. uf does a pretty good job at full function disassembly even when dealing with code shred to pieces by a modern generation/optimization tool, and I can see the number of instructions, blocks etc. –  Remus Rusanu Apr 13 '11 at 23:12

This won't work... what if there's a jump, a dummy ret, and then the target of the jump? Your code will be fooled.

In general, it's impossible to do this with 100% accuracy because you have to predict all code paths, which is like solving the halting problem. You can get "pretty good" accuracy if you implement your own disassembler, but no solution will be nearly as easy as you imagine.

A "trick" would be to find out which function's code is after the function that you're looking for, which would give pretty good results assuming certain (dangerous) assumptions. But then you'd have to know what function comes after your function, which, after optimizations, is pretty hard to figure out.

Edit 1:

What if the function doesn't even end with a ret instruction at all? It could very well just jmp back to its caller (though it's unlikely).

Edit 2:

Don't forget that x86, at least, has variable-length instructions...


For those saying that flow analysis isn't the same as solving the halting problem:

Consider what happens when you have code like:

    jmp foo

You will have to follow the jump each time to figure out the end of the function, and you cannot ignore it past the first time because you don't know whether or not you're dealing with self-modifying code. (You could have inline assembly in your C++ code that modifies itself, for instance.) It could very well extend to some other place of memory, so your analyzer will (or should) end in an infinite loop, unless you tolerate false negatives.

Isn't that like the halting problem?

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@Downvoter: Care to comment? –  Mehrdad Apr 13 '11 at 21:13
It's plenty possible to do this. You don't need to prove anything about whether a given branch is reachable -- which is what you'd need to solve the halting problem for. Enumerating the possible code paths however is flow analysis, which is very much do-able. –  Billy ONeal Apr 13 '11 at 21:14
Basically you'd calculate this the same way cyclomatic complexity is calculated. –  Billy ONeal Apr 13 '11 at 21:16
@Billy: I'm sorry, could you explain a bit more? "Following the code just as the processor does" is called running the program. Aside from the fact that running the program to determine the return value from one function is a terribly inefficient idea, there is no guarantee that the program will even call that function during that run. And you cannot simply start running the program beginning at the function in question, because you don't know what sort of input values the function is expecting - not just function parameters, but also global variable states. –  BlueRaja - Danny Pflughoeft Apr 14 '11 at 16:20
@Billy: But that is what I'm saying - even if you know the function has only one return point, if the jnz jumps into the middle of an instruction, you will have two completely different code paths with (potentially) two different ret statements. How do you know which one is the correct ret (note that this will not always be the "farthest ret")? The only way to know is to know if the jnz will jump or not, which is an undecidable problem. –  BlueRaja - Danny Pflughoeft Apr 14 '11 at 16:59

The real solution to this is to dig into your compiler's documentation. The ARM compiler we use can be made to produce an assembly dump (code.dis), from which it's fairly trivial to subtract the offsets between a given mangled function label and the next mangled function label.

I'm not certain which tools you will need for this with a windows target, however. It looks like the tools listed in the answer to this question might be what you're looking for.

Also note that I (working in the embedded space) assumed you were talking about post-compile-analysis. It still might be possible to examine these intermediate files programmatically as part of a build provided that:

  • The target function is in a different object
  • The build system has been taught the dependencies
  • You know for sure that the compiler will build these object files

Note that I'm not sure entirely WHY you want to know this information. I've needed it in the past to be sure that I can fit a particular chunk of code in a very particular place in memory. I have to admit I'm curious what purpose this would have on a more general desktop-OS target.

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Wow, I use function size counting all the time and it has lots and lots of uses. Is it reliable? No way. Is it standard c++? No way. But that's why you need to check it in the disassembler to make sure it worked, every time that you release a new version. Compiler flags can mess up the ordering.

static void funcIwantToCount()
   // do stuff
static void funcToDelimitMyOtherFunc()
   __asm _emit 0xCC
   __asm _emit 0xCC
   __asm _emit 0xCC
   __asm _emit 0xCC

int getlength( void *funcaddress )
   int length = 0;
   for(length = 0; *((UINT32 *)(&((unsigned char *)funcaddress)[length])) != 0xCCCCCCCC; ++length);
   return length;

It seems to work better with static functions. Global optimizations can kill it.

P.S. I hate people, asking why you want to do this and it's impossible, etc. Stop asking these questions, please. Makes you sound stupid. Programmers are often asked to do non-standard things, because new products almost always push the limits of what's availble. If they don't, your product is probably a rehash of what's already been done. Boring!!!

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Hi Jordan, thank you for this clever (and working!) way to accomplish the task. I actually succeeded without a second static function, just by putting the 0xCCCCCC directly on the main function. I had to manually clean-up the stack via ASM directly. __asm MOV ESP, EBP __asm POP EBP __asm RETN Furthermore to have the exact length of the function without the placeholder I changed ++length to length++ –  Wizche Mar 27 at 15:44

I think it will work on windows programs created with msvc, as for branches the 'ret' seems to always come at the end (even if there are branches that return early it does a jne to go the end). However you will need some kind of disassembler library to figure the current opcode length as they are variable length for x86. If you don't do this you'll run into false positives.

I would not be surprised if there are cases this doesn't catch.

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There is no facilities in Standard C++ to obtain the size or length of a function.
See my answer here: Is it possible to load a function into some allocated memory and run it from there?

In general, knowing the size of a function is used in embedded systems when copying executable code from a read-only source (or a slow memory device, such as a serial Flash) into RAM. Desktop and other operating systems load functions into memory using other techniques, such as dynamic or shared libraries.

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This can work in very limited scenarios. I use it in part of a code injection utility I wrote. I don't remember where I found the information, but I have the following (C++ in VS2005):

#pragma runtime_checks("", off)

static DWORD WINAPI InjectionProc(LPVOID lpvParameter)
    // do something
    return 0;

static DWORD WINAPI InjectionProcEnd()
    return 0;

#pragma runtime_checks("", on)

And then in some other function I have:

size_t cbInjectionProc = (size_t)InjectionProcEnd - (size_t)InjectionProc;

You have to turn off some optimizations and declare the functions as static to get this to work; I don't recall the specifics. I don't know if this is an exact byte count, but it is close enough. The size is only that of the immediate function; it doesn't include any other functions that may be called by that function. Aside from extreme edge cases like this, "the size of a function" is meaningless and useless.

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In C++, the there is no notion of function size. In addition to everything else mentioned, preprocessor macros also make for an indeterminate size. If you want to count number of instruction words, you can't do that in C++, because it doesn't exist until it's been compiled.

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That was the point of using a pointer. (no pun intended) My goal is to get the number of bytes, which is the machine code, that make up the function in memory. –  Adam Apr 13 '11 at 21:14

What do you mean "size of a function"?

If you mean a function pointer than it is always just 4 bytes for 32bits systems.

If you mean the size of the code than you should just disassemble generated code and find the entry point and closest ret call. One way to do it is to read the instruction pointer register at the beginning and at the end of your function.

If you want to figure out the number of instructions called in the average case for your function you can use profilers and divide the number of retired instructions on the number of calls.

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Just set PAGE_EXECUTE_READWRITE at the address where you got your function. Then read every byte. When you got byte "0xCC" it means that the end of function is actual_reading_address - 1.

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Using GCC, not so hard at all.

void do_something(void) { 
   printf("%s!", "Hello your name is Cemetech"); 


   printf("size of function do_something: %i", (int)(&&do_something_END - (int)do_something));
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Is this guaranteed to be accurate? I didn't think that the compiler guaranteed anything about ordering of instructions within a function. –  Yuliy Jan 8 '12 at 17:49

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